ROTARY VARIABLE CAPACITANCE ELEMENT AND ROTARY VARIABLE CAPACITANCE DEVICE
A variable capacitance element of the invention includes: a columnar vibrator formed inside a cylindrical hole of a supporting wall; a first circular driving electrode disposed above the columnar vibrator; a first circular capacitive electrode disposed in the middle of the columnar vibrator; a second circular driving electrode disposed on the periphery of the cylindrical hole of the supporting wall; and a second circular capacitive electrode disposed on an inner side surface of the supporting wall. An electrostatic force is increased or decreased sequentially in the circumferential direction of the second driving electrode that is divided into four parts by sequentially increasing or decreasing the driving voltage in the circumferential direction of the second driving electrode. As a result, the columnar vibrator is rotated to change the electrostatic capacitance between the first capacitive electrode and the second capacitive electrode.
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1. Field of the Invention
The present invention relates to a variable capacitance element and a variable capacitance device, and in particular, to a variable capacitance element that changes an opposite distance between capacitive electrodes using an electrostatic force generated by application of a driving voltage and a variable capacitance device having the variable capacitance element.
2. Description of the Related Art
In general, a variable capacitance element is provided as a variable-capacitance capacitor in an electronic circuit, such as an oscillation circuit and a modulation circuit, in order to change an electrostatic capacitance such that a desired output can be obtained in the electronic circuit. For example, when the variable capacitance element is used in an MEMS, the electrostatic capacitance between electrodes is changed by forming the variable capacitance element in a three-dimensional shape so that the opposite distance between the electrodes can be freely changed.
An example of a known variable capacitance element 102 is shown in
However, in order to increase the electrostatic capacitance between the movable electrode 106 and the fixed electrode 107 in the known variable capacitance element 102, a large driving voltage for increasing the amount of deflection of the cantilever 104 needs to be applied to make the distance between the movable electrode 106 and the fixed electrode 107 small and the state should be maintained. For this reason, it is necessary to continuously apply a large driving voltage in order to obtain a large electrostatic capacitance. As a result, a problem occurs that the power consumption of the variable capacitance element 102 and a variable capacitance device increases.
SUMMARY OF THE INVENTIONTherefore, the invention has been finalized in view of the drawbacks inherent in the related art, and it is an object of the invention to provide a variable capacitance element capable of obtaining a large electrostatic capacitance with small power consumption.
In addition, it is another object of the invention to provide a variable capacitance device includes the variable capacitance element capable of obtaining a large electrostatic capacitance with small power consumption.
In order to achieve the above objects, according to a first aspect of the invention, a variable capacitance element includes: a columnar vibrator that stands up from an insulating surface; a first driving electrode and a first capacitive electrode that are disposed on the periphery of an imaginary ring, which surrounds the columnar vibrator on a side surface of the columnar vibrator, or on the periphery of an imaginary ring located above the columnar vibrator; a second driving electrode that is spaced apart from the first driving electrode to the outside by a predetermined distance so as to be opposite to the first driving electrode and is disposed on the periphery of an imaginary ring that surrounds the columnar vibrator; a second capacitive electrode that is spaced apart from the first capacitive electrode to the outside by a predetermined distance so as to be opposite to the first capacitive electrode and is disposed on the periphery of an imaginary ring that surrounds the columnar vibrator; and a supporting wall that stands up from the insulating surface so as to surround the columnar vibrator and supports the second driving electrode and the second capacitive electrode.
In addition, in the variable capacitance element according to the first aspect of the invention, at least one of the first driving electrode and the second driving electrode are divided into three or more parts and the divided parts are disposed at equal distances. In addition, the columnar vibrator is bent toward an arrangement side of the second driving electrode using a base of the columnar vibrator as a fixed end while being rotated in a circumferential direction of the second driving electrode by sequentially increasing or decreasing a driving voltage applied between the first and second driving electrodes in the circumferential direction of the first driving electrode or the second driving electrode divided into the parts so as to sequentially increase or decrease an electrostatic force generated between the first and second driving electrodes in the circumferential direction, thereby freely changing an opposite distance between the first capacitive electrode and the second capacitive electrode.
In the variable capacitance element according to the first aspect of the invention, it is possible to freely change the opposite distance between the first capacitive electrode and the second capacitive electrode while rotating the columnar vibrator in the circumferential direction by sequentially applying the driving voltage in the circumferential direction. As a result, it is possible to freely change the electrostatic capacitance between the first capacitive electrode and the second capacitive electrode. In addition, since resonance is used for the rotation of the columnar vibrator, it is possible to increase the displacement amount of the columnar vibrator without applying a large driving voltage. As a result, a desired electrostatic capacitance can be obtained with a small driving voltage.
Further, according to a second aspect of the invention, in the variable capacitance element according to the first aspect of the invention, one pair of electrodes of a first pair of electrodes including the first driving electrode and the first capacitive electrode and a second pair of electrodes including the second driving electrode and the second capacitive electrode are arranged to be divided in an up and down direction of the columnar vibrator or the supporting wall, and the other pair of electrodes are arranged on the supporting wall or the columnar vibrator corresponding to arrangement of the one pair of electrodes.
In the variable capacitance element according to the second aspect of the invention, the first capacitive electrode or the second capacitive electrode can be arranged to be close to each other or can be formed in the circular shape without interposing the first capacitive electrode or the second capacitive electrode, which is arranged on the periphery, between the first driving electrode and the second driving electrode that is divided into parts. Accordingly, even if the columnar vibrator is rotated, the electrostatic capacitance between the first capacitive electrode and the second capacitive electrode can be maintained constant without being changed.
Furthermore, according to a third aspect of the invention, in the variable capacitance element according to the first aspect of the invention, one pair of electrodes of a first pair of electrodes including the first driving electrode and the first capacitive electrode and a second pair of electrodes including the second driving electrode and the second capacitive electrode are alternately arranged on the periphery of the same imaginary ring, and the other pair of electrodes are arranged on the supporting wall or the columnar vibrator corresponding to arrangement of the one pair of electrodes.
In the variable capacitance element according to the third aspect of the invention, all electrodes can be arranged near a front end of the columnar vibrator, and accordingly, it is possible to increase the bent amount of the columnar vibrator. As a result, since the opposite distance between the first capacitive electrode and the second capacitive electrode can be made smaller, it is possible to increase the electrostatic capacitance between the first capacitive electrode and the second capacitive electrode.
Furthermore, according to a fourth aspect of the invention, in the variable capacitance element according to the second or third aspect of the invention, one pair of electrodes of the first pair of electrodes and the second pair of electrodes are grounded and are integrally formed.
In the variable capacitance element according to the fourth aspect of the invention, it is not necessary to provide an insulating layer, such as an oxide layer or air, between the first driving electrode and the first capacitive electrode or between the second driving electrode and the second capacitive electrode in one of the pairs of electrodes that are integrally formed. Thus, it is possible to easily form one of the pairs of electrodes that are integrally formed.
Furthermore, according to a fifth aspect of the invention, in the variable capacitance element according to any one of the first to fourth aspects of the invention, the columnar vibrator and the supporting wall are formed by performing reactive ion etching on a single crystal silicon or an SOI (silicon on insulator).
In the variable capacitance element according to the fifth aspect of the invention, the columnar vibrator and the supporting wall that support each of the electrodes can be formed with precision, and accordingly, the opposite distance between the electrodes can be accurately set. In addition, since the SOI is used for the columnar vibrator or the supporting wall, the insulating layer made of the SOI can be used as an insulating surface from which the columnar vibrator and the supporting wall stand up or can be used an insulating layer interposed between the first driving electrode and the first capacitive electrode and between the second driving electrode and the second capacitive electrode.
Furthermore, according to a sixth aspect of the invention, in the variable capacitance element according to the fifth aspect of the invention, the columnar vibrator and the first pair of electrodes are integrally formed using the SOI when the first driving electrode and the first capacitive electrode are not electrically conducted to each other, and the columnar vibrator and the first pair of electrodes are integrally formed using the single crystal silicon or the SOI when the first driving electrode and the first capacitive electrode are electrically conducted to each other.
In the variable capacitance element according to the sixth aspect of the invention, the columnar vibrator can be used as the first driving electrode and the first capacitive electrode by forming the columnar vibrator with the single crystal silicon or the SOI. As a result, it is possible to maintain the opposite distance between the first pair of electrodes and the second pair of electrodes accurate and constant and to omit a process for separately forming the first driving electrode and the first capacitive electrode.
Furthermore, according to a seventh aspect of the invention, in the variable capacitance element according to the fifth or sixth aspect of the invention, the supporting wall and the second pair of electrodes are integrally formed using the SOI when the second driving electrode and the second capacitive electrode are not electrically conducted to each other, and the supporting wall and the second pair of electrodes are integrally formed using the single crystal silicon or the SOI when the supporting wall and the second pair of electrodes are electrically conducted to each other.
In the variable capacitance element according to the seventh aspect of the invention, the supporting wall can be used as the second driving electrode and the second capacitive electrode by forming the supporting wall with the single crystal silicon or the SOI. As a result, it is possible to maintain the opposite distance between the first pair of electrodes and the second pair of electrodes accurate and constant and to omit a process for separately forming the second driving electrode and the second capacitive electrode.
Furthermore, according to an eighth aspect of the invention, in the variable capacitance element according to any one of the first to seventh aspects of the invention, the columnar vibrator is formed in a cylindrical shape, and the supporting wall surrounds the cylindrical columnar vibrator in a circular shape.
In the variable capacitance element according to the eighth aspect of the invention, since the columnar vibrator is formed in the cylindrical shape, the opposite distance between electrodes when the columnar vibrator is rotated is maintained constant. As a result, it is possible to rotate the columnar vibrator while making the columnar vibrator closer to the supporting wall side as compared with a case in which the columnar vibrator having a prismatic shape is made to rotate.
Furthermore, according to a ninth aspect of the invention, in the variable capacitance element according to any one of the first to eighth aspects of the invention, a cover for holding a space between the columnar vibrator and the supporting wall in a vacuum state is further provided.
In the variable capacitance element according to the ninth aspect of the invention, it is possible to remove the air from the space between the columnar vibrator and the supporting wall. As a result, it is possible to prevent the columnar vibrator from damping due to the air when the columnar vibrator is bent toward the supporting wall side and the opposite distance between the first driving electrode and the second driving electrode from being changed.
In addition, in order to achieve the above objects, according to a tenth aspect of the invention, a variable capacitance device includes: the variable capacitance element according to any one of the first to ninth aspects of the invention; and an external power supply that applies a driving voltage, which has the same frequency as a resonating frequency of the columnar vibrator, to the first driving electrode or the second driving electrode that is divided into the parts, a phase of the driving voltage being changed in accordance with an arrangement angle of the first driving electrode or the second driving electrode that is disposed on the periphery of the imaginary ring so as to be divided into the parts.
In the variable capacitance device according to the tenth aspect of the invention, since the resonance can be used for the rotation of the columnar vibrator regardless of the bent amount of the columnar vibrator, it is possible to increase the bent amount of the columnar vibrator without applying a large driving voltage. As a result, a desired electrostatic capacitance can be obtained with a small driving voltage.
Furthermore, according to an eleventh aspect of the invention, in the variable capacitance device according to the tenth aspect of the invention, the external power supply applies a driving voltage having a sinusoidal wave to the divided first or second driving electrode.
In the variable capacitance device according to the tenth aspect of the invention, an increase or decrease in an electrostatic force generated between the first driving electrode and the second driving electrode is smoothly repeated. Accordingly, it is possible to smoothly rotate the columnar vibrator 4A as compared with a case in which a driving voltage having a square wave is applied.
According to the variable capacitance element and the variable capacitance device described above, since the resonance can be used for the rotation of the columnar vibrator without depending on the bent amount of the columnar vibrator, it is possible to obtain the desired electrostatic capacitance even if a driving voltage is small. In addition, according to the variable capacitance element and the variable capacitance device described above, it is possible to obtain a large electrostatic capacitance with small power consumption.
Hereinafter, variable capacitance elements and variable capacitance devices according to first to third embodiments of the invention will be described with reference to
First, a variable capacitance device 1A and a variable capacitance element 2A according to the first embodiment will be described with reference to
The variable capacitance device 1A according to the first embodiment includes the variable capacitance element 2A and an external power supply 3. In addition, as shown in
The columnar vibrator 4A is formed in a cylindrical shape and stands upward from a surface (insulating surface) of an insulating layer 10, as shown in
As shown in
As shown in
Here, a first pair of electrodes 6A and 8A including the first driving electrode 6A and the first capacitive electrode 8A are formed in a closed circular ring shape (correctly speaking, the first driving electrode 6A and the first capacitive electrode 8A have imaginary closed circular ring shapes since the first driving electrode 6A and the first capacitive electrode 8A are formed integrally with the columnar vibrator 4A as will be described later) using a single crystal silicon having a property of a semiconductor, as shown in
The second driving electrode 7A is formed in a ring shape so as to be divided into four equal parts by using a metal having good conductivity, such as Cu and Au, as shown in
The second capacitive electrode 9A is formed in a closed ring shape (correctly speaking, the second capacitive electrode 9A has an imaginary closed ring shape since the second capacitive electrode 9A is formed integrally with the supporting wall 5A as will be described later) using a single crystal silicon having a property of a semiconductor, as shown in
As shown in
For example, in the first embodiment, the diameter of the columnar vibrator 4A is set to 50 Am and the height of the columnar vibrator 4A is 300 μm. Accordingly, in order to set a resonating frequency to 570 kHz, a frequency of a driving voltage is set to 570 kHz and is shifted by 1/(570×4) second (phase difference of 90°) in order to apply the driving voltage to the second driving electrode 7A, which is divided into four equal parts.
Next, a method of manufacturing the variable capacitance element 2A will be described with reference to
The variable capacitance element 2A is manufactured in six processes from a 1A process to a 6A process, as shown in
In the 1A process, insulating surface layers 31a and 31b shown in
Then, in the 2A process, as shown in
Thereafter, in the 3A process, a seed layer (not shown) formed by using a Ti layer with the thickness of 15 nm and a seed layer (not shown) formed by using a Cu layer with the thickness of 100 nm are formed on a surface of the insulating surface layer 31b on the bottom surface 30b and a surface of the oxide layer 31c of the cylindrical hole 33, respectively, by using a sputtering method, as shown in
Then, in the 4A process, a cylindrical projection 34 shown in
In the 5A process, a seed layer (not shown) and a resist film (not shown) are sequentially formed on the surface of the oxide layer 31d formed in the 4A process and the surface exposed from the oxide layer 31d by etching, predetermined patterning is performed on the resist film, and then a metal having good conductivity, such as Cu and Au, is electroplated on the seed layer exposed from the resist film. As a result, the circular second driving electrode 7A that is opened to be divided into four equal parts and the cylindrical second extended electrode 13 used for the second capacitive electrode 9A are formed as shown in
Then, in the 6A process, as shown in
Next, the variable capacitance device 1A and the variable capacitance element 2A according to the first embodiment will be described with reference to
The variable capacitance device 1A according to the first embodiment includes the variable capacitance element 2A and the external power supply 3, as shown in
Here, as shown in
In addition, the rotation radius of the columnar vibrator 4A is proportional to the maximum intensity of an electrostatic force, that is, a maximum driving voltage. Accordingly, by totally increasing or decreasing the maximum driving voltage, it becomes possible to freely change the opposite distance between the first capacitive electrode 8A and the second capacitive electrode 9A. As described above, it is possible to easily change the electrostatic capacitance between the first capacitive electrode 8A and the second capacitive electrode 9A to a desired capacitance.
In the first embodiment, particularly important points of operations of the variable capacitance device 1A and the variable capacitance element 2A are that the variable capacitance device 1A and the variable capacitance element 2A cause the columnar vibrator 4A to vibrate by rotating the columnar vibrator 4A. As for a vibration frequency (or the number of rotations) of the columnar vibrator 4A, the number of rotations that allows rotation to be performed without requiring a large driving force, that is, a resonating frequency (the number of resonating rotations) exists. By applying a driving voltage, which has the same frequency as the resonating frequency of the columnar vibrator 4A, to the second driving electrode 7A, it is possible to rotate the columnar vibrator 4A with a driving voltage smaller than a driving voltage (driving voltage required in a known variable capacitance element) required only for causing the front end 4Ae of the columnar vibrator 4A to be bent toward the side where the second driving electrode 7A is disposed. That is, since it is possible to increase the amount of displacement of the columnar vibrator 4A without applying a large driving voltage by using resonance for the rotation of the columnar vibrator 4A, the electrostatic capacitance can be obtained with a small driving voltage.
In addition, as shown in
Moreover, in the variable capacitance element 2A according to the first embodiment, it is necessary to rotate the columnar vibrator 4A while maintaining the opposite distance between the first capacitive electrode 8A and the second capacitive electrode 9A constant in order to obtain a desired electrostatic capacitance. Therefore, the variable capacitance element 2A according to the first embodiment is configured as follows.
As shown in
In addition, as shown in
In this case, since the variable capacitance element 2A is used as an MEMS, the columnar vibrator 4A and the supporting wall 5A are very small. Accordingly, it is not easy to precisely form the columnar vibrator 4A and the supporting wall 5A. Therefore, in the variable capacitance element 2A according to the first embodiment, the columnar vibrator 4A having a circular shape that supports the first pair of electrodes 6A and 8A and the supporting wall 5A that supports the second pair of electrodes 7A and 9A can be precisely formed by etching a single crystal silicon in an SOI (silicon-on insulator) so as to form the columnar vibrator 4A and the supporting wall 5A. In such a manner, the opposite distance between electrodes can be precisely set.
In addition, as shown in
Since the first pair of electrodes 6A and 8A are grounded and integrally formed, an insulating layer such as an oxide layer or air does not need to be interposed between the first driving electrode 6A and the first capacitive electrode 8A, unlike a case in which the first pair of electrodes 6A and 8A are separately formed in a state where the first pair of electrodes 6A and 8A are spaced apart from each other. Accordingly, the first pair of electrodes 6A and 8A can be easily formed. In addition, by integrally forming the columnar vibrator 4A and the first pair of electrodes 6A and 8A using a single crystal silicon, the columnar vibrator 4A having a satisfactory formation precision can be used as the first driving electrode 6A and an first capacitive electrode 8A. As a result, it is possible to maintain the opposite distance between the first pair of electrodes 6A and 8A and the second pair of electrodes 7A and 9A accurate and constant, and it is possible to omit processes for separately forming the first driving electrode 6A and the first capacitive electrode 8A.
That is, in the variable capacitance device 1A and the variable capacitance element 2A according to the first embodiment, resonance can be used for the rotation of the columnar vibrator 4A regardless of the bent amount of the columnar vibrator 4A. Accordingly, a desired electrostatic capacitance can be obtained even if a driving voltage is small. As described above, the variable capacitance device 1A and the variable capacitance element 2A according to the first embodiment are advantageous in that a large electrostatic capacitance can be obtained with small power consumption.
Furthermore in the first embodiment, although the second driving electrode 7A is disposed to be divided into four equal parts as shown in
In addition, in order to increase a value of electrostatic capacitance obtainable from the variable capacitance element 2A, a plurality of variable capacitance elements 2A can be formed to thereby obtain the electrostatic capacitance corresponding to the number of formed variable capacitance elements 2A, as shown in
Next, a variable capacitance device 1B and a variable capacitance element 2B according to a second embodiment will be described with reference to
The variable capacitance device 1B according to the second embodiment includes the variable capacitance element 2B, which is shown in
As shown in
As shown in
As shown in
In addition, the supporting wall 5B has an insulating surface layer 11, which is formed on a top surface thereof by oxidation, in order to support the second driving electrode 7B divided into a plurality of parts while maintaining an insulation property. Here, a single crystal silicon is selected as a material used for the supporting wall 5B from the point of view of how easily the supporting wall 5B can be formed and how precisely the supporting wall 5B can be formed. The supporting wall 5B is formed integrally with the insulating layer 10 using an SOI wafer 30. In addition, as shown in
As shown in
Here, as shown in
In the same manner as the first capacitive electrode 8A in the first embodiment, the first capacitive electrode 8B is formed in a closed circular ring shape (correctly speaking, imaginary closed ring shapes) using a single crystal silicon and is disposed on the periphery of an imaginary circular ring, which surrounds the columnar vibrator 4B, on the outer side surface 4Bb of the columnar vibrator 4B. As is apparent from
As shown in
As shown in
In addition, the shapes of the second driving electrode 7B and the second capacitive electrode 9B described above are greatly different from the shapes of the second driving electrode 7A and the second capacitive electrode 9A, as shown in
As shown in
Next, a method of manufacturing the variable capacitance element 2B according to the second embodiment will be described with reference to FIGS. Here,
The variable capacitance element 2B is manufactured in six processes from a 1B process to a 6B process, as shown in
In the 1B process, insulation surface layers 31a and 31b are formed by oxidizing a top surface 30a and a bottom surface 30b of the SOI wafer 30, as shown in
In the 2B process, as shown in
Then, in the 3B process, an oxide layer 31c is formed on an inner surface of the cylindrical hole 33 formed in the 2B process and then a seed layer (not shown), which is formed by using a Ti layer with the thickness of 15 nm and a Cu layer with the thickness of 100 nm, are formed on a surface of the insulating surface layer 31b on the bottom surface 30b and a surface of the oxide layer 31c of the cylindrical hole 33, as shown in
In the 4B process, as shown in
In the 5B processes, a resist film is formed on portions corresponding to the upper end surfaces 4Bc and 5Bc of the columnar vibrator 4B and the supporting wall 5B by means of resist patterning and a portion that is not patterned is etched using the Deep-RI. By this etching, the columnar vibrator 4B (including the first capacitive electrode 8B), the supporting wall 5B (including the second capacitive electrode 9B), and the third extended electrode 14 are formed using an upper silicon 30c of the SOI wafer 30, as shown in
In the 6B processes, as shown in
Next, operations of the variable capacitance device 1B and the variable capacitance element 2B according to the second embodiment will be described with reference to
The variable capacitance device 1B according to the second embodiment includes the variable capacitance element 2B and the external power supply 13, as shown in
In addition, the first capacitive electrode 8B is disposed below the first driving electrode 6B (correctly speaking, the first capacitive electrode 8B is formed integrally with the columnar vibrator 4B, that is, imaginarily disposed) and the second capacitive electrode 9B is disposed below the second driving electrode 7B (correctly speaking, the second capacitive electrode 9B is formed integrally with the supporting wall 5B, that is, imaginarily disposed). Accordingly, as the columnar vibrator 4B is rotated, an opposite distance between the first capacitive electrode 8B and the second capacitive electrode 9B is decreased. As a result, the electrostatic capacitance between the first capacitive electrode 8B and the second capacitive electrode 9B is increased. As described above, it is possible to easily change the electrostatic capacitance between the first capacitive electrode 8B and the second capacitive electrode 9B to a desired capacitance.
In addition, in the same manner as in the first embodiment, a large electrostatic capacitance can be obtained with a small driving voltage by rotating the columnar vibrator 4B in a resonating frequency. Moreover, in the same manner as in the first embodiment, it is possible to smoothly rotate the columnar vibrator 4B by applying a driving voltage having a sinusoidal wave to the second driving electrode 7B.
The variable capacitance element 2B according to the second embodiment is greatly different from the variable capacitance element 2A according to the first embodiment in that the first capacitive electrode 8B is not formed integrally with the first driving electrode 6B and the first capacitive electrode 8B is not grounded, as shown in
In addition, effects that can be obtained through the up and down arrangement of the second driving electrode 7B and the second capacitive electrode 9B, formation of the columnar vibrator 4B having the cylindrical shape and circular surrounding of the supporting wall 5B, etching of the columnar vibrator 4B and the supporting wall 5B that is performed with a silicon or an SOI using the RIE, and integral formation of the columnar vibrator 4B and the first capacitive electrode 8B and integral formation of the supporting wall 5B and the second capacitive electrode 9B are the same as those in the first embodiment.
Next, a variable capacitance device 1C and a variable capacitance element 2C according to a third embodiment will be described with reference to
The variable capacitance device 1C according to the third embodiment includes the variable capacitance element 2C, which is shown in
As shown in
In the same manner as in the first embodiment, the first driving electrode 6C and the first capacitive electrode 8C are formed integrally with the columnar vibrator 4C and are supported on the columnar vibrator 4C as a surface layer of the columnar vibrator 4C. In addition, a first extended electrode 12 serving as an extended electrode for the first driving electrode 6C and the first capacitive electrode 8C is formed in the same manner as in the first embodiment. The first extended electrode 12 extends passing through the insulator 10 of the SOI from a base 4Cd of the columnar vibrator 4C.
The shapes of the second driving electrode 7C and the second capacitive electrode 9C that are supported by the supporting wall 5C are different from those of the second driving electrode 7A and the second capacitive electrode 9A in the first embodiment. As shown in
Next, operations of the variable capacitance device 1C and the variable capacitance element 2C according to the third embodiment will be described with reference to
The variable capacitance device 1C according to the third embodiment includes the variable capacitance element 2C shown in
Here, a second pair of electrodes 7C and 9C including the second driving electrode 7C and the second capacitive electrode 9C are alternately arranged on the same periphery of an imaginary circular ring which surrounds an upper end of the columnar vibrator 4C. In addition, a first pair of electrodes 6C and 8C including the first driving electrode 6C and the first capacitive electrode 8C are formed integrally with the columnar vibrator 4C. That is, the first pair of electrodes 6C and 8C are imaginarily disposed on the upper end of the columnar vibrator 4C in correspondence with the arrangement of the second pair of electrodes 7C and 9C. Accordingly, as the columnar vibrator 4C is rotated, the opposite distance between the first capacitive electrode 8C and the second capacitive electrode 9C is decreased. As a result, the electrostatic capacitance between the first capacitive electrode 8C and the second capacitive electrode 9C is increased. As described above, it is possible to easily change the electrostatic capacitance between the first capacitive electrode 8C and the second capacitive electrode 9C to a desired capacitance.
The variable capacitance element 2C according to the third embodiment is characterized in that the first driving electrode 6C, the first capacitive electrode 8C, the second driving electrode 7C, and the second capacitive electrode 9C are arranged on the same periphery above the outer side surface 4Cb of the columnar vibrator 4C or on the upper end surface 5Cc of the supporting wall 5C. If the first driving electrode 6C, the first capacitive electrode 8C, the second driving electrode 7C, and the second capacitive electrode 9C are arranged on the same periphery, when the columnar vibrator 4C is deflected toward the second driving electrode 7C side due to the electrostatic force, the opposite distance between the first capacitive electrode 8C and the second capacitive electrode 9C can be made smaller than that in the case where the first driving electrode 6C, the first capacitive electrode 8C, the second driving electrode 7C, and the second capacitive electrode 9C are arranged in the up and down direction like the first embodiment (refer to the first embodiment or the second embodiment).
In addition, since the second capacitive electrode 9C can be made of a metal by forming the second capacitive electrode 9C on the upper end surface 5Cc of the supporting wall 5C by plating, it is possible to obtain a larger electrostatic force than in a case in which the first driving electrode 6B is formed of a silicon like the first embodiment.
In addition, effects that can be obtained through application of a driving voltage having a sinusoidal wave, formation of the columnar vibrator 4C having the cylindrical shape and circular surrounding of the supporting wall 5C, etching of the columnar vibrator 4C and the supporting wall 5C that is performed with a silicon or an SOI using the RIE, and integral formation of the columnar vibrator 4C and the first capacitive electrode 8C and integral formation of the supporting wall 5C and the second capacitive electrode 9C are the same as those in the first embodiment.
That is, in the variable capacitance devices 1A to 1C and the variable capacitance elements 2A to 2C according to the first to third embodiments, resonance can be used for the rotation of each of the columnar vibrators 4A to 4C without depending on the bent amount of each of the columnar vibrators 4A to 4C. Accordingly, a desired electrostatic capacitance can be obtained even if a driving voltage is small. Therefore, an effect that a large electrostatic capacitance can be obtained with small power consumption is achieved.
In addition, the invention is not limited to the embodiments described above but various changes and modifications thereof could be made as needed.
For example, as shown in
In addition, at least one of the first driving electrode 6D and the second driving electrode 7D may be divided. Accordingly, as shown in
Moreover, although not shown, in a variable capacitance element according to still another embodiment, it is preferable to include a cover for holding a space between a columnar vibrator and a supporting wall in a vacuum state in order to prevent the columnar vibrator from damping due to air existing between the columnar vibrator and the supporting wall when the columnar vibrator is bent toward the supporting wall side and an opposite distance between a first driving electrode and a second driving electrode from being changed. The shape and size of the cover does not matter as long as the cover has a vacuum holding function. Since the air can be removed from the space between the columnar vibrator and the supporting wall due to the cover, it is possible to reduce or eliminate an adverse effect of damping caused by the air existing between the columnar vibrator and the supporting wall.
Claims
1. A rotary variable capacitance element comprising:
- a columnar vibrator that stands up from an insulating surface;
- a first driving electrode and a first capacitive electrode that are disposed on the periphery of an imaginary ring, which surrounds the columnar vibrator on a side surface of the columnar vibrator, or on the periphery of an imaginary ring located above the columnar vibrator;
- a second driving electrode that is spaced apart from the first driving electrode to the outside by a predetermined distance so as to be opposite to the first driving electrode and is disposed on the periphery of an imaginary ring that surrounds the columnar vibrator;
- a second capacitive electrode that is spaced apart from the first capacitive electrode to the outside by a predetermined distance so as to be opposite to the first capacitive electrode and is disposed on the periphery of an imaginary ring that surrounds the columnar vibrator; and
- a supporting wall that stands up from the insulating surface so as to surround the columnar vibrator and supports the second driving electrode and the second capacitive electrode,
- wherein at least one of the first driving electrode and the second driving electrode are divided into three or more parts and the divided parts are disposed at equal distances, and
- the columnar vibrator is bent toward an arrangement side of the second driving electrode using a base of the columnar vibrator as a fixed end while being rotated in a circumferential direction of the second driving electrode by sequentially increasing or decreasing a driving voltage applied between the first and second driving electrodes in the circumferential direction of the first driving electrode or the second driving electrode divided into the parts so as to sequentially increase or decrease an electrostatic force generated between the first and second driving electrodes in the circumferential direction, thereby freely changing an opposite distance between the first capacitive electrode and the second capacitive electrode.
2. The rotary variable capacitance element according to claim 1,
- wherein one pair of electrodes of a first pair of electrodes including the first driving electrode and the first capacitive electrode and a second pair of electrodes including the second driving electrode and the second capacitive electrode are arranged to be divided in an up and down direction of the columnar vibrator or the supporting wall, and
- the other pair of electrodes are arranged on the supporting wall or the columnar vibrator corresponding to arrangement of the one pair of electrodes.
3. The rotary variable capacitance element according to claim 1,
- wherein one pair of electrodes of a first pair of electrodes including the first driving electrode and the first capacitive electrode and a second pair of electrodes including the second driving electrode and the second capacitive electrode are alternately arranged on the periphery of the same imaginary ring, and
- the other pair of electrodes are arranged on the supporting wall or the columnar vibrator corresponding to arrangement of the one pair of electrodes.
4. The rotary variable capacitance element according to claim 2,
- wherein one pair of electrodes of the first pair of electrodes and the second pair of electrodes are grounded and are integrally formed.
5. The rotary variable capacitance element according to claim 1,
- wherein the columnar vibrator and the supporting wall are formed by performing reactive ion etching on a single crystal silicon or an SOI (silicon on insulator).
6. The rotary variable capacitance element according to claim 5,
- wherein the columnar vibrator and the first pair of electrodes are integrally formed using the SOI when the first driving electrode and the first capacitive electrode are not electrically conducted to each other, and
- the columnar vibrator and the first pair of electrodes are integrally formed using the single crystal silicon or the SOI when the first driving electrode and the first capacitive electrode are electrically conducted to each other.
7. The rotary variable capacitance element according to claim 5,
- wherein the supporting wall and the second pair of electrodes are integrally formed using the SOI when the second driving electrode and the second capacitive electrode are not electrically conducted to each other, and
- the supporting wall and the second pair of electrodes are integrally formed using the single crystal silicon or the SOI when the supporting wall and the second pair of electrodes are electrically conducted to each other.
8. The rotary variable capacitance element according to claim 1,
- wherein the columnar vibrator is formed in a cylindrical shape, and
- the supporting wall surrounds the cylindrical columnar vibrator in a circular shape.
9. The rotary variable capacitance element according to claim 1, further comprising:
- a cover for holding a space between the columnar vibrator and the supporting wall in a vacuum state.
10. A rotary variable capacitance device, comprising:
- the rotary variable capacitance element according to claim 1; and
- an external power supply that applies a driving voltage, which has the same frequency as a resonating frequency of the columnar vibrator, to the first driving electrode or the second driving electrode that is divided into the parts, a phase of the driving voltage being changed in accordance with an arrangement angle of the first driving electrode or the second driving electrode that is disposed on the periphery of the imaginary ring so as to be divided into the parts.
11. The rotary variable capacitance device according to claim 10,
- wherein the external power supply applies a driving voltage having a sinusoidal wave to the divided first or second driving electrode.
Type: Application
Filed: Oct 9, 2007
Publication Date: May 8, 2008
Patent Grant number: 7511937
Applicant: ALPS ELECTRIC CO., LTD. (Tokyo)
Inventor: Shinji MURATA (Fukushima-ken)
Application Number: 11/869,700
International Classification: H01G 5/011 (20060101); H01G 5/16 (20060101);